Low power email functionality for an electronic device

ABSTRACT

Low power email capabilities are provided for an electronic device, such as a hand-held portable computer having capability to operate an application during a low power mode. During the low power mode, portions of hardware, software, services, and/or other components of the portable computer that are not necessary for email-related operations, such as polling a server for new email, are suspended or otherwise deactivated. At least a portion of a new email is stored in a memory of a low power display module (LPDM) of the portable computer. The LPDM is provided with its own low-power processing unit, user interface, and other components to allow access to and manipulation of the stored email while other components of the portable computer remain deactivated.

CROSS REFERENCE TO RELATED APPLICATION

The present application claims the benefit under 35 U.S.C. §119(e) ofU.S. Provisional Patent Application Ser. No. 60/504,165, entitled“SOFTWARE AND HARDWARE FEATURES FOR MINI-PC,” filed Sep. 18, 2003,assigned to the same assignee as the present application and which isincorporated by reference in its entirety.

TECHNICAL FIELD

The present disclosure relates generally to electronic devices, and inparticular but not exclusively, relates to a low power emailfunctionality for an electronic device, such as a hand-held portablecomputer, having the capability to run applications while in a low powermode.

BACKGROUND INFORMATION

Today's computer users are highly mobile individuals. Whether onbusiness trips, on vacations, or coming to and from work, theseindividuals are readily identifiable by their use of laptops,enhanced-functionality cellular telephones, Palm Pilots™, Blackberries™,and other portable electronic devices. Indeed, many establishmentsprovide Internet connections that cater to individuals who may be merelypassing through the establishment for a short period of time and whorequire a network connection. For instance, Internet connections areavailable at airports and hotels, and even in restaurants and coffeeshops.

Because of the portable nature of the electronic devices, there arecertain limits to their capabilities. Power consumption is one of theprime examples. Power consumption is generally a minor issue in anoperating environment where the user has “plugged” the electronic deviceinto an electrical power outlet or has docked the electronic device intoa docking station. In these situations, there is constant andsubstantially unlimited power for operating the electronic device,thereby eliminating the need for the electronic device to consume powerfrom an internal power source, such as an internal battery, whileplugged in.

However despite the proliferation of establishments that provideInternet connections (and typically a corresponding stationary powersupply), there are still many instances when a stationary power supplyis unavailable to the highly mobile user. In these instances, theelectronic device needs to rely on its internal battery to supply thepower necessary to run applications or to perform other functions withthe electronic device.

If operated in a full power mode using power from the internal battery,the electronic device can generally operate for only a few hours beforethe battery is drained. In fact, many different software services,software applications, and hardware can run concurrently in the fullpower mode using various subsystems and components in the electronicdevice. A display, disk drive, and processor (especially a graphicsprocessor) are some of the components of an electronic device that canrun concurrently, yet consume a substantial amount of power.

To help reduce power consumption, especially when a stationary powersupply is unavailable, many electronic devices include a “standby” modein which the electronic device turns OFF and/or substantially reducespower to all of its subsystems and components. In such a standby mode, auser generally cannot use any applications unless the electronic deviceis switched from the standby mode to the full power mode. As such, itcan often be necessary for the user to make only limited and veryefficient use of the electronic device while it is in full power modewhen there are no available stationary power supplies. Furthermore, itmay even be necessary for the user to keep the electronic devicecompletely turned off or in a substantially non-functional standby modeas much as possible.

If the user fails to diligently conserve power in this manner, then theelectronic device will run out of power and become unusable until theuser can recharge or replace the internal battery and/or connect to astationary power supply. For instance, repeatedly accessing a hard diskdrive when running applications can dramatically reduce the amount ofavailable power that can be delivered from an internal battery. Theconstant need for software applications to access the hard disk drive isan important reason for limiting or eliminating the functionality of theapplications in the standby mode. This constrained operating environmentis inconvenient and impractical for a highly mobile user who may wish touse a portable electronic device for certain applications, such asemail, when there are no available stationary power supplies.

BRIEF SUMMARY OF THE INVENTION

One preferred aspect provides a method usable for an electronic devicethat can operate in a low power mode. The method includes monitoring foran event representative of a transition to the low power mode. If theevent is detected, the method activates an email component to operateduring the low power mode. The email component is used to obtain atleast a portion of an email during the low power mode. The method loadsin a memory the portion of the email, and presents the loaded portion ofthe email from the memory.

BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWINGS

Non-limiting and non-exhaustive embodiments are described with referenceto the following figures, wherein like reference numerals refer to likeparts throughout the various views unless otherwise specified.

FIG. 1 is a front, top right isometric view of an example electronicdevice, which in this case is in the form of a hand-held portablecomputer including a lid shown in an open position.

FIG. 2 is a front, top right isometric view of the example portablecomputer of FIG. 1 including the lid shown in a closed position.

FIG. 3 is a block diagram of an embodiment of the portable computer anda representative operating environment in more detail.

FIG. 4 is a diagrammatic representation of power states in accordancewith one embodiment.

FIG. 5 is a diagrammatic representation of interaction and operation ofvarious components of the portable computer in view of the power statesof FIG. 4, according to one embodiment.

FIG. 6 is a block diagram that illustrates operation of an emailsynchronization component of FIG. 5 in conjunction with other componentsof the portable computer, according to one embodiment.

FIG. 7 is a block diagram showing an embodiment of the emailsynchronization component of FIG. 5 in more detail.

FIG. 8 is a flowchart illustrating operation of the low power emailapplication according to one embodiment.

DETAILED DESCRIPTION

Embodiments of techniques to provide low power email functionality foran electronic device, for example, a portable electronic device in theform of a hand-held portable computer are described herein. In thefollowing description, numerous specific details are given to provide athorough understanding of embodiments. The invention can be practicedwithout one or more of the specific details, or with other methods,components, materials, etc. In other instances, structures, materials,or operations are not shown or described in detail to avoid obscuringaspects of the invention.

Reference throughout this specification to “one embodiment” or “anembodiment” means that a particular feature, structure, orcharacteristic described in connection with the embodiment is includedin at least one embodiment. Thus, the appearances of the phrases “in oneembodiment” or “in an embodiment” in various places throughout thisspecification are not necessarily all referring to the same embodiment.Furthermore, the particular features, structures, or characteristics maybe combined in any suitable manner in one or more embodiments.

As an overview, an embodiment provides low power email functionality foran electronic device having the capability to operate an applicationduring a low power mode. A non-limiting example of such an electronicdevice is a portable electronic device. The electronic device, accordingto one embodiment, comprises a hand-held portable computer. The lowpower email functionality can be provided when the portable computer isin a low power mode. In this low power mode, most of the applications,services, devices, processes, and other components of the portablecomputer are turned OFF or otherwise powered down. However, certaincomponents (and the resources needed to support their operation) can beselectively kept powered during the low power mode.

One such component is an email synchronization component that canoperate during the low power mode in conjunction with an emailapplication. In an embodiment, emails are cached or otherwise storedlocally in a first storage location of the portable computer by theemail application while the portable computer is operating at a fullpower mode. During a synchronization process, the emails stored in thefirst storage location are copied to a second storage location by theemail synchronization component, wherein the second storage location cancomprise a cache or other memory located in a low power display module(LPDM) of the portable computer. The synchronization may be performedduring the full power mode, low power mode, or other operative powermode by the email synchronization component. In an embodiment, the LPDMis integrated on a lid of the portable computer, and can include its ownoperating system, low power processing unit, application(s), userinterface, communication devices, and/or other components.

When the lid of the portable computer is closed, the portable computerenters into a standby power mode or other similar power state. Duringspecific time intervals, the portable computer “wakes up” from thestandby power mode and enters into the low power mode. During the lowpower mode, hardware and/or software components associated with theemail synchronization component and/or the email application areactivated such that the portable computer can poll for new email. Thatis, according to one embodiment, certain components that are usable forpolling or otherwise checking for new email are selectively and/orsequentially activated. If there is any new email, this new email isdownloaded or otherwise stored in the second storage unit in the LPDM.The user can then read older previously cached emails and/or any newlydownloaded emails via the user interface of the LPDM, after the downloadis complete and the portable computer has returned to the standby powermode.

In one embodiment, the components associated with a high powerprocessing unit, the associated operating system, communication device,email application, and/or other components in the portion of theportable computer external to the LPDM are activated during the lowpower mode to perform the polling for new email. If there is new email,this new email is provided to the LPDM for presentation on a userinterface of the LPDM using the low-power processing unit of the LPDM.

In another embodiment, components of the LPDM (such as its low-powerprocessing unit, operating system, communication device, and/or othercomponents) are used to perform the email polling and otheremail-related operations. In yet another embodiment, a combination ofcomponents in both the LPDM and in the portion of the portable computerexternal to the LPDM can be activated during the low power mode toperform email polling and/or other email-related operations.

In one embodiment, the low power mode is applicable to the high-powerprocessing unit in that this high-power processing unit enters the lowpower mode to poll for new email, perform synchronization, and/or otheremail-related operations. The low-power processing unit is generally ineither an active or inactive power state, irrespective of the particularoperating power mode of the high-power processing unit. The low-powerprocessing unit transitions into its active power state, for example: 1)if the LPDM is used to present downloaded emails, 2) if/when the LPDMperforms the email polling, 3) if synchronization is being performed, or5) if other email-related operations involving the LPDM are performedand while the high-power processing unit is in a reduced power mode(such as either or both the standby or low power modes). The low-powerprocessing unit can be inactive otherwise.

During operation of the portable computer in the low power mode,hardware, software, services, and other components of the portablecomputer that are not necessary for email-related operations aresuspended or otherwise deactivated. Furthermore, as each email-relatedtask is performed, the components that are not needed for subsequenttasks are deactivated and reactivated as needed. The variousdeactivation operations can be performed in sequence from thehighest-level components to the lowest-level components to ensure thatcomponents that are needed by other components, or that are otherwiseinvolved in operating dependencies with other components, are notprematurely deactivated. A specific set of events can transition theportable computer out of the low power mode into some other operatingmode, such as the full power mode.

By using the low power mode to poll and retrieve emails at particulartime intervals and using only activated components relevant to suchoperations while keeping other components deactivated, power consumptionfor the portable computer 100 can be reduced. Moreover, by using thelow-power processing unit to present information related to such emails(such as inbox listings, email portions, etc.) on the user interface ofthe LPDM, power consumption is reduced as compared to using thehigh-power processing unit and main display at full operating power toperform such activities.

FIGS. 1-2 show front, top right isometric views of an example electronicdevice, in this case a hand-held portable computer 100 in which anembodiment may be implemented. While the portable computer 100 is usedas the illustrative example throughout this application, otherembodiments may be implemented with devices that may not necessarily bethought of as a “computer” or with devices that may not necessarily havethe same shape and appearance as the portable computer 100 illustratedin FIGS. 1-2. Examples include but are not limited to wirelesscommunication devices, display devices, monitors, audiovideo equipment,consumer electronic devices, or other electronic devices that canimplement applications that are usable during a low power mode.

As shown, the portable computer 100 is similar in appearance to a laptopcomputer, in that it comprises first and second portions 102 and 104,respectively, which are hinged. The first portion 102 can include akeypad or keyboard 110 and housing for the internal electroniccomponents (such as one or more processors, machine-readable storagemedia, graphics drivers, and so forth). The second portion 104 operatesas a lid that folds over the first portion 102 (when in a closedposition, such as shown in FIG. 2), and includes a display screen 108for displaying information or for otherwise presenting data (such asemails, user interfaces, graphics, and the like) while the secondportion 104 is unfolded to an upright position as shown in FIG. 1.

Unlike a conventional laptop computer, however, the portable computer100 of one example embodiment is substantially smaller in size in termsof both volume and weight. For example, the portable computer 100 may be140 mm long, 101 mm wide, and 30 mm thick (while closed), with a weightof approximately one pound. The display screen 108 on the second portion104 may have a resolution comparable to a desktop computer monitor. Ingeneral, the size of the display screen 108, the size of the internalcomponents (e.g., chips and circuit boards) located within the firstportion 102, and the strategic placement of the internal components(e.g., density), and other factors will influence the overall formfactor of the portable computer 100. As illustrated in FIGS. 1-2, theportable computer 100 has a size such that it can be held securely in ahand 106 of a user whether in the open or closed position. In anotherembodiment, the portable computer 100 may have a larger or otherwisedifferent form factor and/or have a greater weight.

In one specific embodiment shown in FIG. 2, the portable computer 100can include a low power display 114 integrated within the second portion104. In such an embodiment, the low power display 114 be used to presentcertain information (such as email) while the lid of the portablecomputer 100 is closed and the portable computer 100 is in the low powermode, or be used to present other forms of data. The low power display114 also includes a user interface through which the user can interactwith low power mode applications (such as an application that presentsan email inbox), trigger the portable computer 100 to transition to thelow power mode, and other operations. For example, the low power display114 can present an email inbox, email folders, email commands/menus,calendar and task information, or other information usable with an emailapplication. In an embodiment, the low power display 114 and itsassociated user interface (as well as other components of the secondportion 104) can be integrated as part of the LPDM.

While the low power display 114 is depicted in FIG. 2 as beingpositioned on the surface of the second portion 104, the low powerdisplay 114 may be positioned elsewhere on the portable computer 100.For example, the low power display 114 may be positioned on sidesurfaces, the bottom surface, or any combination of surfaces of theportable computer 100.

In one embodiment that will be described below, the portable computer100 of FIG. 1 includes a lid switch 112. The lid switch 112 operates asa type of trigger to indicate whether the lid of the portable computer100 is open or closed. Thus, for example, when the lid of the portablecomputer 100 is closed as shown in FIG. 2, the lid switch 112 can makephysical contact with an electromechanical connection, can changeorientation, can be depressed, or experience any other type of change instate that causes a signal such as an interrupt to occur. Such aninterrupt can be used by an operating system, a basic input/outputsystem (BIOS), a service, or other software component to initiate atransition from one power state to another power state (e.g., to the lowpower mode). The lid switch 112 can be embodied with any suitable shape,mechanism, functionality, or other operating feature.

Examples of the portable computer 100 in which embodiments of the lowpower mode email techniques may be implemented are disclosed in U.S.patent application Ser. No. 10/338,802, entitled “SYSTEM AND METHOD FORHEAT REMOVAL FROM A HAND-HELD PORTABLE COMPUTER WHILE DOCKED”; U.S.patent application Ser. No. 10/338,815, entitled “NAVIGATION ANDSELECTION CONTROL FOR A HAND-HELD PORTABLE COMPUTER”; U.S. patentapplication Ser. No. 10/338,761, entitled “HEAT DISSIPATION FROM AHAND-HELD PORTABLE COMPUTER”; and U.S. patent application Ser. No.10/338,791, entitled “KEYBOARD WITH MOUSE FOR A HAND-HELD PORTABLECOMPUTER”, all filed Jan. 7, 2003, assigned to the same assignee as thepresent application, and all of which are incorporated herein byreference in their entireties. Also assigned to the same assignee andincorporated by reference are U.S. application. Ser. No. 10/857,628,entitled “METHOD AND APPARATUS FOR OPERATING AN ELECTRONIC DEVICE IN ALOW POWER MODE,” and U.S. application Ser. No. 10/857,627, entitled “LOWPOWER MEDIA PLAYER FOR AN ELECTRONIC DEVICE,” both of which were filedMay 28, 2004 and which disclose low power mode-related embodiments.

FIG. 3 and the accompanying discussion provide a description of asuitable computing environment in which embodiments can be implemented.Although not required, embodiments will be described in the generalcontext of hardware and computer-executable instructions, such asprogram application modules, objects, drivers, services, or macros beingexecuted by a computer (such as by the portable computer 100). Inaddition to the embodiment shown in this figure, other embodiments canbe practiced with other computer systems and/or network configurations.

FIG. 3 shows a computing system 300, and in particular shows anembodiment of the portable computer 100 in more detail. The computingsystem 300 includes the portable computer 100 and a server computingsystem 302. The server computing system 302 may be located at one ormore network locations, for example, at one or more Internet ServiceProvider (ISP) locations to store and serve email information and toserve other information for the portable computer 100.

The portable computer 100 includes a high-power processing unit 304 forhigh-power processing, at least one system memory 306, and a system bus308 that couples various system components, including the system memory306, to the high-power processing unit 304. The high-power processingunit 304 may be any logic processing unit, such as one or more centralprocessing units (CPUs), digital signal processors (DSPs), graphicsprocessors, application-specific integrated circuits (ASICs), etc.

In an embodiment, the portable computer 100 may also include a low-powerprocessing unit 310 for low power processing, and which may or may notnecessarily operate with the same operating system as the high-powerprocessing unit 304. For example, in one embodiment separate operatingsystems, memory, applications, or other components can be provided forthe high-power processing unit 304 and for the low-power processing unit310. It is also possible in an embodiment for the high-power processingunit 304 and for the low-power processing unit 310 to share certaincomponents, rather than having separate dedicated components. In anembodiment, the LPDM integrated in the second portion 104 of theportable computer 100 can include or be otherwise operatively coupled tothe low-power processing unit 310 and/or to other components.

The system bus 308 can employ any suitable bus structure orarchitecture, including a memory bus with memory controller, aperipheral bus, and a local bus. The system memory 306 may include oneor more read-only memories (ROMs) 311 and one or more random accessmemories (RAMs) 312. In one embodiment, separate ROM 311, RAM 312,and/or other memory can be dedicated for the low power display 114. Forexample, separate memory (such as a cache, ROM, RAM, and the like) canbe provided in the LPDM such that emails can be stored in that memoryand accessed (and manipulated) during the low power mode. For the sakeof simplicity of illustration and explanation, the various memoriesand/or other components that can be provided additionally/separately forthe LPDM are depicted in FIG. 3 as single units (but neverthelesslabeled in the plural sense).

A BIOS 314, which can be stored in the ROM 311, contains routines thathelp transfer information between elements within the portable computer100, such as during start-up. Operation of an embodiment of the BIOS 314in connection with a low power mode will be described in further detailbelow.

The portable computer 100 may include a hard disk drive 316 for readingfrom and writing to a hard disk 318. The hard disk drive 316communicates with the high-power processing unit 304 via the system bus308. The hard disk drive 316 may include interfaces or controllers (notshown) coupled between such drive(s) and the bus 308. The hard diskdrive 316 and its associated hard disk 318 provide nonvolatile orotherwise persistent storage of computer readable instructions, datastructures, program modules and other data for the portable computer100. Although the depicted portable computer 100 employs the hard diskdrive 316 and the hard disk 318, other types of drives andcomputer-readable media that can store data accessible by a computer maybe employed, such as compact disks (CDs), magnetic cassettes, flashmemory cards, digital video disks (DVDs), Bernoulli cartridges, RAMs,ROMs, smart cards, etc. In one embodiment, the hard disk drive 316and/or other drives are not integrated within a housing of the portablecomputer 100 itself, but instead are external devices that areaccessible via hardwire or wireless communication interfaces.

The system memory 306 can be used for storing various program modules,such as one or more operating systems 320, one or more applicationprograms 322 (such as an email program or other applications that canoperate in a high power mode or in a low power mode), other programs ormodules 324, and program data 326. For simplicity of illustration, thesystem memory 306 is shown in FIG. 3 as a single unit with multiplecomponent parts. While illustrated as such, this example illustration isalso intended to cover an embodiment wherein the second portion 104 ofthe portable computer 100 (or more particularly the LPDM integrated inthe second portion 104) includes its own system memory 306, RAM 312,operating system 320, and the like.

A non-limiting example of an operating system 320 that may be used isWindows XP™, which is commercially available from Microsoft Corporationof Redmond, Wash. Windows XP™ as well as other suitable operatingsystems used with certain embodiments may include a power managementsubsystem. In an embodiment, power management capabilities are providedin connection with the low power mode that supplements power managementprovided by the power management subsystem of the operating system 320.

The other programs/modules 324 can include libraries, applicationprogram interfaces (APIs), objects, or other components. The programdata 326 can include cached data, such as cached emails or other typesof files, in one embodiment. As such, parts of the system memory 306provide volatile or otherwise non-persistent memory capability, (such asan operating system cache, the RAM 312, or other cache or non-persistentstorage location) for storing emails.

The program data 326 can be stored as a data structure, file, or otherdata format in a cache, database, or other storage unit integrated in orseparate from the system memory 306. In one embodiment, the program data326 also includes power profiles and other power management dataindicative of the power requirements of particular services, software,and hardware of the portable computer 100. As will be described later,this power management data is used in one embodiment to determine whichcomponent of the portable computer 100 to keep ON or to turn OFF duringthe low power mode, length of time to keep ON or OFF, sequence ofturning various components ON or OFF, and other parameters and settings.Further detailed discussion of the various other programs/modules 324that interact for managing and controlling operations in the low powermode and of the application program 322 (and more specifically, sometype of suitable low power mode application program or component) willbe provided below.

The portable computer 100 may also include a web browser 328 forpermitting the portable computer 100 to access and exchange data withsources such as Internet web sites, corporate intranets, extranets,and/or other networks as described below, as well as other serverapplications on server computers. For purposes of clarity the browser328 is shown separately in FIG. 3. According to various embodiments, thebrowser 328 can comprise one of the application programs 322, one of theother programs/modules 324, and/or may be integrated in some manner withthe operating system(s) 320. While shown in FIG. 3 as being stored inthe system memory 306, the operating systems 320, application programs322, other programs/modules 324, program data 326, and browser 328 canbe stored on the hard disk 318 of the hard disk drive 316 and/or othercomputer-readable media in another embodiment.

Moreover and as discussed above, the various elements depicted as beingstored in the system memory 306 need not necessarily reside on the samephysical memory. For example, in embodiments where the low-powerprocessing unit 310 and the low power display 114 comprise part of theLPDM that can be operatively detached from the portable computer 100 orotherwise operate independently of other components of the portablecomputer 100, separate memory (having an operating system, RAM, ROM,applications, and other elements stored thereon) can be operativelydecoupled from the portable computer 100 along with the low-powerprocessing unit 310 and the low power display 114. In this manner, theLPDM can be used during the low power mode to present emails that havebeen cached in the LPDM.

A user can enter commands and information into the portable computer 100through one or more input devices (such as the keyboard 110) and apointing device (such as a mouse 330 that may be, for example, builtinto the keyboard 110, an example embodiment of which is disclosed inU.S. patent application Ser. No. 10/338,791), or through such othertypes of devices usable for providing user input. Alternatively oradditionally, the mouse 330 can be embodied as a touch pad as comparedto physical buttons. Another input device may take the form of one ormore buttons 332 on the side of the keyboard 110, with the button(s) 332usable for scrolling and clicking via turning and pressing of thebutton(s) 332. Other possible input devices can include a microphone,joystick, game pad, scanner, etc. (not shown). These and other inputdevices are connected to the high-power processing unit 304 through aninterface 334 such as a serial port interface that couples to the bus308, although the portable computer 100 may employ other interfaces suchas a parallel port, a game port or a wireless interface or a universalserial bus (USB). The interface 334 can be any suitable communicationinterface to the bus 308 and need not necessarily be a port per se. Inone embodiment, the input devices such as a mouse, joystick, game pad,keyboard, etc. are integrated directly into the housing of the portablecomputer 100, rather than or in addition to being coupleable via aserial or parallel port interface.

The display screen 108 operates as the main display and is coupled tothe bus 308 via a graphics interface 336, such as a video adapter orother graphics component that will allow video and other graphics to berendered on the display screen 108. The low power display 114 (and itsassociated user interfaces) may also be present in one embodiment toallow presentation of data (e.g., presentation on the outside surface ofthe second portion 104 of the portable computer 100) during the lowpower mode, when the lid is closed on the portable computer 100. The lowpower display 114 may be coupled to the bus 308 by way of the graphicsinterface 336 (or other interface) or may be directly coupled to the bus308. The low power display 114 can provide its user interface withvarious controls, such as buttons and menus, which may be used tocontrol various aspects of email-related operations during the low powermode, such as reading, deleting, or saving emails. Also as depicted inFIG. 3, the lid switch 112 can be coupled to the system bus 308 to allowthe various components of the portable computer 100 to detect andrespond to a closing or opening of the lid of the portable computer 100.

The portable computer 100 can operate in a networked environment usinglogical connections to one or more remote computers and/or devicesexternal to the portable computer 100, such as the server computingsystem 302 and a network device 340, such as a printer or networkstorage unit. The portable computer 100 is logically connected to one ormore remote computing systems or devices under any suitable method ofpermitting computers to communicate, such as through a wireless localarea network (WLAN) 342, a wireless wide area network (WWAN), or anyother network 344, including wired and wireless networks that use or cancommunicate with the Internet (e.g., World Wide Web). Variousembodiments can be implemented to communicate with several types ofcommunication networks, including but not limited to, telecommunicationsnetworks, cellular networks, paging networks, wired and wirelessenterprise-wide computer networks, intranets, extranets, the Internet,and other types of networks. Examples of wireless systems and protocolswith which the portable computer 100 can communicate, include but arenot limited to, Wi-Fi, Bluetooth, 802.11, and others.

When used in a LAN networking environment, the portable computer 100 canbe connected to the LAN 342 through one or more adapters or networkinterfaces 346 (communicatively linked to the bus 308). In anembodiment, separate network interfaces 346 can be provided for use bythe high-power processing unit 304 and for use by the low-powerprocessing unit 310 in the LPDM. When used in a WWAN or other network344, the portable computer 100 may include one or more modems,transceivers 348 or other devices, such as the network interface 346,for establishing communications over this networking environment or forotherwise communicating with external devices. The transceiver 348 asshown in FIG. 3 is communicatively linked between the interface 334 andthe network 344. The transceiver 348 may be one or more transmitters,receivers, or other communication devices that are compliant with, forexample, 802.11, GPS, Bluetooth, cellular (TDMA, FDMA, and/or CDMA),Wi-Fi, virtual private network (VPN), and/or other communicationstandards or techniques. In an embodiment, a separate transceiver 348can be provided for the LPDM.

In one embodiment, the portable computer 100 is communicatively linkedto the server computing system 302 through the LAN 342 and/or thenetwork 344 with transmission control protocol/Internet protocol(TCP/IP) middle layer network protocols or other network protocollayers, such as User Datagram Protocol (UDP). The network connectionsshown in FIG. 3 are only some examples of establishing communicationlinks between computers, and other links can be used, including bothhardwire and wireless links.

The server computing system 302 includes one or more servers 350. In thecontext of email, the server 350 can comprise an email server. Anexample of such a server is a Microsoft Exchange™ server, and theprinciples described herein are not to be limited to only emailimplementations that use a Microsoft Exchange™ server.

FIG. 4 is a diagrammatic representation 400 of power states inaccordance with one embodiment. More particularly, FIG. 4 showsoperating power states S0-S2 and S3-S5 that are supported by theAdvanced Configuration and Power Interface (ACPI) specification and anon-ACPI-defined low power mode state S2.5 in accordance with oneembodiment. Typically, the S0-S2 and S3-S5 power states are defined inpower profiles that are integrated as part of a power managementsubsystem (such as a Windows power management subsystem) in theoperating system 320. For the sake of brevity, only a summary of theACPI power states will be provided herein. Further details of the ACPIpower states can be found in Compac Computer Corporation et al.,“Advanced Configuration and Power Interface Specification,” Revision2.0c, Aug. 25, 2003. Moreover, another embodiment of the invention canbe based on power states that are not necessarily compliant with theACPI specification.

In the S0 power state, the high-power processing unit 304 is executinginstructions at its full clock speed, and the portable computer 100 isotherwise operating at substantially full (e.g., 100%) capacity. Forinstance, many services are operational and performing their tasks, datais being written to and read from the hard disk drive 316, the maindisplay screen 108 is rendering content, and other working state tasksare being performed.

The S1 power state is a sleeping-low wake mode. In the S1 power state,the high-power processing unit 304 (or other processing unit) is notexecuting instructions. Processor context is maintained, and all systemclocks and memory are in refresh. The S2 power state is also asleeping-low wake mode that is logically lower than the S1 power state,and is assumed to conserve more power. The processor context is notmaintained, and the clock of the high-power processing unit 304 isstopped. Moreover, all system clocks, cache(s) and memory are inrefresh, and all power resources that supply a system-level reference ofS0 or S1 are in the OFF state. The S1 and S2 power states are low wakemodes in that any interrupt (such as the pressing of a key on thekeyboard 110) generally awakens or transitions the portable computer 100from these modes.

The S3 power state is a standby mode and is logically a lower powerstate than the S2 power state. Memory is continuously running andrefreshed, and so the data context of the RAM 312 is maintained, forinstance. However, the high-power processing unit 304, componentsassociated with the graphics system, the hard disk drive 316, the maindisplay screen 108, and other components of the portable computer 100are turned OFF and no services are running. In one embodiment, a fewspecific actions awaken the portable Computer 100 from the S3 powerstate, such as pressing a power button, opening the lid of the portablecomputer 100 (thus activating the lid switch 112), and the receipt of awake-on-LAN/USB/fax signal.

In the S4 power state, the portable computer 100 is in a hibernate mode.The data context of the RAM 312 is not maintained, and most componentsare turned OFF and not running. The S5 power state is logically thelowest power state, and is a soft OFF mode that requires a completeboot-up when awakened.

In accordance with an embodiment, an intermediate power state isprovided between the S2 and S3 power states. This is a low power modeand non-ACPI-defined power state, which is labeled in FIG. 4 as thepower state “S2.5.” The label “S2.5” is used herein merely for the sakeof convenience and ease of explanation and to provide context, and isnot intended to limit the invention to strictly an ACPI environment.

In an embodiment of the S2.5 power state, most of the components of theportable computer 100 are turned OFF. However, a low power modeapplication (such as components usable with an email application) isoperating, and the various components of the portable computer 100 thatare usable to support operation of that low power mode application areselectively ON or otherwise running, until such components are no longerneeded during operation of the low power mode application (in which casesuch components are then turned OFF). The speed of the clock in thehigh-power processing unit 304 is also reduced to a minimum low speed tosupport the low power mode application. For instance, the speed of theclock during the low power mode can be set to a minimum speed that isspecified for the high-power processing unit 304, a non-limiting andpurely illustrative example of which is approximately 433 MHz. As such,for transitioning to and operating in the S2.5 power state, the sequenceand duration of turning OFF certain unnecessary components can minimizepower consumption. Moreover, the portable computer 100 will not beawakened from the S2.5 power state by any basic interrupt (as contrastedwith the S1 or S2 power states). Rather, only specific events will causea transition to a higher power state (e.g., S0), such as opening the lidof the portable computer 100. Further details of low power modeoperation in the S2.5 power state, including transitioning to and fromthe low power mode, are provided below.

FIG. 5 is a diagrammatic representation 500 illustrating the interactionand operation of various components of the portable computer 100 in viewof the power states of FIG. 4, according to one embodiment. Moreparticularly, the diagrammatic representation 500 illustrates operationof the portable computer 100 in the low power mode (i.e., the S2.5 powerstate).

The BIOS 314 includes a real time clock (RTC) 502, a bootloader 504, anda CPU minimum clock and throttle 506. According to one embodiment, theBIOS 314 includes a low power mode subsystem 508, which interacts withother low power mode components to control and manage transitions to andfrom the S2.5 power state, and to manage and control the switching ofcertain components (generally hardware-related components) OFF or ON inconnection with low power mode operation. The low power mode subsystem508 can be embodied in software source code, software object code, orother machine-readable instructions. In one embodiment, the CPU minimumclock and throttle 506 can be used to set or otherwise control thetiming interval to transition from an S3 standby power state, forexample, into the low power mode for purposes of polling for new email.Furthermore, the BIOS 314 can control and manage transitions into andout of the S0 and S3 power states, as indicated in FIG. 5.

Transitioning or otherwise entering into the S2.5 power state (or alsoentering the S3 power state) according to one embodiment can beperformed by closing the lid of the portable computer 100, therebytriggering or otherwise activating the lid switch 112. Additionally,exiting the S2.5 power state (or also exiting the S3 power state) can beperformed by opening the lid of the portable computer 100, which alsotriggers a change in state of the lid switch 112. An arrow 516 in FIG. 5represents the entering into and exiting from the S2.5 power state. Thearrow 516 indicates that the entering/exiting may be performed by a BIOScall, an interrupt, or other communication to the BIOS 314 from the lidswitch 112. When entering the low power mode of the S2.5 power state,the low power mode subsystem 508 of the BIOS 314 then wakes up a lowpower mode service 520 (indicated by an arrow 522). Alternatively oradditionally, a broken arrow 518 represents that the transition to orfrom the S2.5 power state can be performed by a direct communication (asa result of activation of the lid switch 112) to the low power modeservice 520 from the lid switch 112.

In an embodiment, entering the S2.5 power state also can be performedvia a low power display module (LPDM) 510 that includes the low powerdisplay 114. The LPDM 510 includes a user interface 512 (which can beembodied as controls, buttons, or menus on the low power display 114)that can communicate (indicated with an arrow 525) with the low powermode subsystem 508 of the BIOS 314 to initiate transition into the S2.5power state. Alternatively or additionally, the user interface 512 orother component of the LPDM 510 can communicate directly with the lowpower mode service 520 (also represented by the broken arrow 518) toinitiate transition into the S2.5 power state. Further alternatively orin addition, the LPDM 510 (including its user interface 512) cancommunicate with an LPDM application service 524 (indicated by an arrow526) to initiate transition into the S2.5 power state or to otherwisepresent information during the low power mode (such as presentation ofemail on the low power display 114). A user 514 can operate the lidswitch 112 or the LPDM 510 to trigger a transition into the full powermode or any of the low power modes.

According to various embodiments, the LPDM 510 can include its ownoperating system 511 that can operate in conjunction with the low-powerprocessing unit 310 of the LPDM 510. The LPDM 510 can also include oneor more applications 513 and a memory 515, such as a cache. An exampleof the application 513 is an application to perform bi-directionalsynchronization of email between email content of the memory 515 andemail content present in the system memory 306 (and/or at the server350). The application 513 can also provide functionality for the userinterface 512, such as rendering an inbox on the low power display 114,allowing emails listed in the inbox to be opened, deleted, moved, etc.,and other email-related operations. According to an embodiment, the LPDM510 can also include or otherwise be operatively coupled to its ownnetwork access device 517 (such as a transceiver 348 or networkinterface 346), so that the LPDM 510 can perform email polling/retrievalalternatively or additionally to the email polling/retrieval performedby the high-power processing unit 304 during the low power mode.

The low power mode service 520 of one embodiment comprises a service,program, component, subroutine, module, or other software code or set ofmachine-readable instructions that is always running. In the S0 powerstate, the low power mode service 520 is running but is basicallyperforming a minimal amount of tasks, or more specifically, the lowpower mode service 520 is monitoring for certain activities that signala need to transition to the S2.5 power state. An example of such amonitored activity is activation of the lid switch 112, which indicatesa closing or opening of the lid of the portable computer 100.

When the lid is closed or some other activity signals a need totransition to the low power mode of the S2.5 state, the low power modeservice 520 wakes up or otherwise becomes more active, and determineswhich low power mode application is to be made active in the low powermode (if any); determines the hardware, software, and power needs forthat low power mode application from information provided by the lowpower mode application and/or from power profiles comprising part of theprogram data 324; communicates with either or both the BIOS 314 or withan operating system kernel 528 (as indicated by an arrow 532) to turncertain elements OFF in a specific sequence; or otherwise performs tasksassociated with operating the portable computer 100 in the low powermode. The arrow 522 also represents this communication to the BIOS 314by the low power mode service 520, and an arrow 532 represents thecommunication to the operating system kernel 528 by the low power modeservice 520. The operating system kernel 528 and/or the BIOS 314 canthen selectively begin powering down unnecessary hardware, software,services, and other elements. In the context of email in one embodiment,the arrow 522 also represents the turning ON and OFF of the low powermode subsystem 508 of the BIOS 314, to allow activation and deactivationof elements of the portable computer 100 (such as the transceiver 348)that are used for periodic polling of an external server (such as theserver 350) for new email.

In an embodiment, the low power mode service 520 sends asuspend-until-resume (as compared to suspend-until-interrupt) message toeither or both the operating system kernel 528 and the BIOS 314, so asto suspend tasks that are not needed or unused during the low powermode. When a resume signal is sent from the low power mode service 520,the suspended tasks are resumed from the point where they weresuspended. It is noted that an embodiment removes these tasks fromsuspension with a resume signal, as compared to an interrupt. Aninterrupt often removes elements from a standby state in existingsystems. However, with an embodiment, interrupts are generated whileoperating in the low power mode, and therefore, resume signals ratherthan interrupts are used to remove elements from suspension to ensurethat such elements remain suspended during the low power mode and do notperform unnecessary tasks (and therefore unnecessarily consume power).

The low power mode service 520 can comprise part of the program/modules324 shown in FIG. 3. In one embodiment, the low power mode service 520comprises a service that can be written using the Microsoft Win32Software Development Kit (SDK), so as to allow the service to interactand interface with the operating system kernel 528. The operating systemkernel 528, such as a Windows XP™ kernel, can in turn comprise part ofthe overall operating system 320.

In the case of the operating system kernel 528, it can make calls to theBIOS 314 to turn ON or turn OFF certain elements during the S1-S5 powerstates, as represented by an arrow 530. In one embodiment, this includesdirect BIOS calls to the low power mode subsystem 508 to turn OFFcertain hardware elements that are not necessary for the low power mode.Alternatively or additionally, the operating system kernel 528 can turnOFF certain software elements, such as unnecessary services 536 orapplications, by turning OFF their corresponding drivers 534. Theoperating system kernel 528 can also selectively turn ON such services536 or applications by activating their drivers 534.

In an embodiment operating in the low power mode, the low power modeservice 520 and/or the LPDM application service 524 interact with one ormore email synchronization components 538 and with one or more low powerapplications 539. An embodiment of the low power application 539 is alow power media player disclosed in U.S. application Ser. No.10/857,627, entitled “LOW POWER MEDIA PLAYER FOR AN ELECTRONIC DEVICE,”filed May 28, 2004. The low power application 539 of one embodiment cancontrol or otherwise operate with an installed application 556, such asa media player application, as depicted by an arrow 552.

With respect to an embodiment of the email synchronization component538, this element can comprise a dynamic link library (DLL), applicationprogram, API, executable code, software module, COM server, service,library, or other type of machine-readable instruction. In anembodiment, the email synchronization component 538 can use at leastsome of the existing functionality and/or features of an application 548(e.g., an email application, such as Microsoft Outlook™, Eudora™, LotusNotes™, and so on) to perform email retrieval and caching or otheremail-related operations. An arrow 549 depicts this cooperation betweenthe application 548 and the email synchronization component 538. Inanother embodiment, the email synchronization component 538 can beprovided with its own mail retrieval mechanism and other email-relatedfunctionality, instead of using the functionality in the application548.

One embodiment of the synchronization component 538 is shown in FIG. 7.The email synchronization component 538 includes executable code 700that uses one or more mail retrieval mechanisms 702 to poll or otherwiseobtain new email from the server 350 or other email source. The mailretrieval mechanism(s) 702 can include, for example, any one or more ofMAPI, POP3, IMAP, HTTP, or any other mail retrieval mechanism. Theexecutable code 700 can also include functionality for placing theretrieved email in a local storage location (such as the RAM 312) andfor performing synchronization or other communication with the LPDM 510.This communication with the LPDM 510 can be performed via the LPDMapplication service 524 (indicated by an arrow 554 in FIG. 5) and/or viathe low power mode service 520 and/or directly therewith.

The email synchronization component 538 can further include any one ormore of an API 704 or other component(s) 708 to support email-relatedoperations associated with polling, caching, synchronizing, and thelike.

In an embodiment, a network access component 540 (either or bothwireless or wired) can be selectively activated during the low powermode. Examples of the network access component 540 include thetransceiver 348 or the network interface 346. The email synchronizationcomponent 538 can use the network access component 540 to check theserver 350 and then download any new email into a disk cache 542 orother suitable volatile memory location as needed during the low powermode, wherein the disk cache 542 can comprise part of the RAM 312 orother storage unit.

FIG. 6 is a block diagram 600 that illustrates operation of the emailsynchronization component 538 in conjunction with other components ofthe portable computer 100, according to one embodiment. Certain elementsfrom the diagrammatic representation 500 of FIG. 5 are also shown in theblock diagram 600 so as to provide context.

First, the low power mode service 520 is shown. The low power modeservice 520 uses information from a power mode data store 618, whichincludes the program data 326 shown in FIG. 3, to determine whichelements of the portable computer 100 should be kept turned ON or turnedOFF, and to determine the power needs of certain elements for certainapplications or operations. The sequence and duration for turning suchelements ON or OFF can be stored in and obtained from the power modedata store 618. In an embodiment, the power mode data store 618 caninclude information such as the power requirements for the transceiver348 and/or network interface 346 so that these components cancommunicate with the server 350 to obtain new email, identification ofthe resources that need to be turned ON during operation of theapplication 548 and/or the email synchronization component 538 duringthe low power mode, power requirements of such resources, when suchresources need to be turned ON/OFF and any corresponding duration, andother information associated with operation of the email synchronizationcomponent 538 and/or application 548. An arrow 602 represents thecapability of the low power mode service 520 to obtain this informationfrom the power mode data store 618. A power profile editor 604 or othertool can be provided to add, modify, or remove any of the power profileinformation in the power mode data store 618.

The low power mode service 520 can control or otherwise communicate witha plurality of different clients 606. Such clients 606 can include thelow power application 539, for example a low power media player. The lowpower mode service 520 can further communicate with a low power modeuser interface, such as a user interface on the low power display 114via the LPDM application service 524 or directly thereto. The low powermode service 520 can also communicate directly (or via the LPDMapplication service 524) with the email synchronization component 538.

Through the LPDM application service 524 and/or an API 608, the emailsynchronization component 538 can communicate with the user interface512 of the LPDM 510, to present email on the user interface 512.

There may be other clients 610 with which the email synchronizationcomponent 538 interacts during its operation in the low power mode. Someof these clients 610 include the hard disk drive 316, the hard disk 318,the high-power processing unit 304, the operating system 320, and/orother components. As shown in FIG. 6, the email synchronizationcomponent 538 can also communicate with the application 548 (such as anemail application) if certain features of the application 548 are beingused for purposes of email retrieval, synchronization, presentation ofemail, and the like.

Email retrieval and synchronization is illustrated in FIG. 6. The emailsynchronization component 538 uses the mail retrieval mechanism of theapplication 548 to poll the server 350 for the purpose of determining ifnew email is available. If new email is available, then the emailsynchronization component 538 will then download and store at least aportion of the new email in the disk cache 542, which is located in thefirst portion 102 of the portable computer 100. This polling and storingcan be performed in a full power mode, in the low power mode (e.g., whencertain components of the portable computer 100 are awakened from thestandby state, so that such components can perform the polling), or inany other operative power mode of the high-power processing unit 304.

To synchronize, the email synchronization component 538 replicates atleast some of the contents of the disk cache 542 into the memory 515,which is located in the LPDM 510. This synchronization may also beperformed during the full power mode, the low power mode, or any otheroperative power mode. Arrows 612 and 614 depict this synchronization.The arrows 612 and 614 of one embodiment are bi-directional to representthat the synchronization can also be performed from the memory 515 tothe disk cache 542.

FIG. 8 shows a flowchart 800 illustrating the manner in which email canbe provided during the low power mode in accordance with one embodiment.Features represented by the flowchart 800 can be embodied in softwaresource, software object code, or in other machine-readable instructionsstored on a machine-readable medium. The various operations need notnecessarily be performed in the exact order shown, and some operationscan be added, removed, modified, or combined.

In a block 802, the portable computer 100 may be operating in a fullpower mode. In this block, the lid of the portable computer 100 is open,and the user is actively using one or more applications, such as theemail application 548 or some other application. The email retrievalmechanism of the application 548 may be retrieving new emails from theserver 350 or other email source. During this full power mode, the emailsynchronization component 538 can perform email synchronization toreplicate at least some of the retrieved email stored in the disk cache542 into the memory 515 in the LPDM 510.

At a block 804, the portable computer 100 transitions into the standbymode or other substantially inoperative mode. In one embodiment, closingthe lid of the portable computer 100 triggers this transition. While inthe standby mode, the clock and throttle 506 of the high-powerprocessing unit 304, user-defined settings, or other mechanism(s) areused to monitor the next time interval when the portable computer 100 isto transition from the standby mode to the low power mode. When thatparticular time interval arrives, the portable computer 100 transitionsinto the low power mode at a block 806.

At the block 806, the low power mode service 520 performs certain tasksto transition into the low power mode. These tasks include reading thelow power mode power profile from the power mode data store 618, anddetermining which elements of the portable computer 100 to turn OFF, tokeep turned ON, when to turn them OFF or ON, in which sequence,duration, and so forth in connection with polling for and retrievingemail, storing retrieved email, and/or synchronizing. The devices,services, processes, and other components that are unused for emailpolling, storing, and/or synchronizing are kept turned OFF and/orsuspended. In an embodiment, the transition into the low-power modeinvolves selective activation of components that operate in conjunctionwith the high-power processing unit 304, such that the high-powerprocessing unit 304 can control activation of the transceiver 348 and/ornetwork interface 346 to retrieve email, storage of retrieved emails inthe disk cache 542, and/or activation of the email synchronizationcomponent 538 so that this component can synchronize the contents of thedisk cache 542 with the contents of the memory 515 in the LPDM 510.

In another embodiment, transition into the low power mode can involveactivation of the email synchronization component 538, withoutactivation of other components associated with the high-power processingunit 304 (such as the transceiver 348). For instance, in an embodimentwhere the LPDM 510 is provided with its own network access device 517,the email synchronization component 538 can cooperate with that networkaccess device 517 to download new email directly into the memory 515without requiring an intermediate download into the disk cache 542.

The polling and retrieval, storage, and/or synchronization are performedat a block 808. After completing the operations at the block 808, theportable computer 100 can return to the standby mode or otherwise returnto a substantially inoperative power state of the high-power processingunit 304. At this point, the newly downloaded emails or portionsthereof, if any, have been copied into the memory 515 and can beaccessed and viewed at least in part via the LPDM 510.

For example at a block 812, the low-power processing unit 310 isoperating and controlling the LPDM 510. The LPDM 510 can display (on theuser interface 512) an inbox having the new emails, such as subject,sender, date, or other portions of the email. The user can choose toread, delete, save, move, or perform other operations to access andmanipulate the emails. For instance, the user can choose to read justthe displayed portion of the email, and decide to defer reading theentire email until later. The user may also instead choose to read theentire email after reading the portion displayed on the user interface512. In such a case, the user can open the lid of the portable computer100, thereby causing the portable computer 100 to transition into thefull power mode. The particular email can then be displayed and read onthe display screen 108.

When the portable computer 100 transitions back into the full power modeor other operative power mode (such as the low power mode),synchronization can be performed as needed by the email synchronizationcomponent 538 at the block 814. For instance, if the user deleted ormoved emails via the LPDM 510, then the contents of the memory 515 arereplicated by the email synchronization component 538 in the disk cache542 and/or at the server 350. Transitioning back to an operative powermode at the block 814 can be caused by several possible actions, such asopening the lid of the portable computer 100, user-activation of one ormore buttons or commands, or other actions.

All of the above U.S. patents, U.S. patent application publications,U.S. patent applications, foreign patents, foreign patent applicationsand non-patent publications referred to in this specification and/orlisted in the Application Data Sheet, are incorporated herein byreference, in their entirety.

The above description of illustrated embodiments, including what isdescribed in the Abstract, is not intended to be exhaustive or to limitthe invention to the precise forms disclosed. While specific embodimentsand examples are described herein for illustrative purposes, variousequivalent modifications are possible and can be made without deviatingfrom the spirit and scope of the invention.

For example, while some embodiments have been described in the contextof interacting with a Windows XP™ kernel and operating in conjunctionwith the power states defined in the ACPI specification, the inventionis not limited to these specific implementations. Other embodiments maybe implemented with electronic devices that use a different operatingsystem and/or that have power states that are defined using some otherspecification.

These and other modifications can be made to the invention in light ofthe above detailed description. The terms used in the following claimsshould not be construed to limit the invention to the specificembodiments disclosed in the specification and the claims. Rather, thescope of the invention is to be determined entirely by the followingclaims, which are to be construed in accordance with establisheddoctrines of claim interpretation.

1. A method usable for an electronic device that can operate in astandby mode, a low power mode, and a higher power mode, wherein thestandby mode uses less power than the low power mode and the low powermode uses less power than the higher power mode, the method comprising:in the higher power mode, operating an email application to obtain atleast a portion of a first email under control of a first processor in ahigh power processing module; displaying the portion of the first emailon a first display controlled by the high power processing module usingthe first processor, wherein the first display is viewable when theelectronic device is in an open configuration; transitioning theelectronic device to the standby mode, wherein transitioning includesdeactivating or reducing power to the high power processing module;monitoring for an event representative of a transition from the standbymode to the low power mode; in response to detecting the event,activating an email component to operate during the low power mode;deactivating at least a first component of the electronic device that isto be unused for obtaining at least a portion of a second email duringthe low power mode; activating at least a second component of theelectronic device that is to be used in conjunction with the emailcomponent for obtaining the at least a portion of the second emailduring the low power mode; using the email component to obtain the atleast a portion of the second email during the low power mode;deactivating the second component after the at least a portion of thesecond email is obtained; loading the portion of the second email to amemory associated with a low power processing module separate from thehigh power processing module by a second processor in the low powerprocessing module; and using the second processor, displaying the loadedportion of the second email from the memory on a second displaycontrolled by the low power processing module, wherein the seconddisplay is viewable when the electronic device is in a closedconfiguration, wherein the electronic device has a lid and the firstdisplay is located on an inside surface of the lid, and wherein thesecond display is physically separate from the first display and thesecond display is located on an outside surface of the lid.
 2. Themethod of claim 1 wherein presenting the loaded portion of the secondemail from the memory includes presenting the loaded portion of thesecond email while other components of the electronic device are at ainoperative power state.
 3. The method of claim 1 wherein: obtaining atleast the portion of the second email during the low power mode includesdownloading the portion of the second email to a storage location usinga delivery mechanism of an email application installed in the electronicdevice; and wherein if the downloaded portion of the second emailincludes content, loading in the memory the portion of the second emailincludes synchronizing at least some of the email content in the storagelocation to the memory.
 4. The method of claim 3, further comprisingsynchronizing email contents in the memory to the storage location,after user manipulation of the email contents in the memory.
 5. Themethod of claim 1 wherein using the email component to obtain theportion of the second email during the low power mode includes using theemail component along with a selectively activated network access deviceof the electronic device to obtain the portion of the second email. 6.The method of claim 5 wherein the network access device is associatedwith the low-power processing module of the electronic device and isdifferent from a network access device associated with the high powerprocessing module of the electronic device.
 7. The method of claim 1,wherein the memory associated with the low power processing module is asecond memory and wherein the second memory is physically separate fromthe first memory, further comprising: storing the portion of the firstemail in a first memory associated with the high power processingmodule; synchronizing the portion of the first email from the firstmemory to the second memory; presenting the synchronized portion of thefirst email from the second memory using the second display controlledby the low power processing module.
 8. An article of manufacture usablefor a portable electronic device that can operate in a standby mode, alow power mode, and a higher power mode, wherein the standby mode usesless power than the low power mode and the low power mode uses lesspower than the higher power mode, the article of manufacture comprising:a machine-readable storage medium having instructions stored thereon tocause a processor to process email during a low power mode, by: in thehigher power mode, operating an email application to obtain at least aportion of a first email under control of a high power processingmodule; displaying the portion of the first email on a first displaycontrolled by the high power processing module, wherein the firstdisplay is viewable when the portable electronic device is in a firstconfiguration; transitioning the portable electronic device to thestandby mode, wherein transitioning includes deactivating or reducingpower to the high power processing module; monitoring for an eventrepresentative of a transition from the standby mode to the low powermode; in response to detecting the event, activating an email componentto operate during the low power mode; deactivating at least a firstcomponent of the portable electronic device that is to be unused forobtaining at least a portion of a second email during the low powermode; activating at least a second component of the portable electronicdevice that is to be used in conjunction with the email component forobtaining the at least a portion of the second email during the lowpower mode; using the email component to obtain the at least a portionof the second email during the low power mode; deactivating the secondcomponent after the at least a portion of the second email is obtained;loading the portion of the second email to a memory associated with alow power processing module separate from the high power processingmodule; and presenting the loaded portion of the second email from thememory on a second display controlled by low power interface associatedwith the low power processing module, wherein the second display isphysically separate from the first display and wherein the seconddisplay is viewable when the portable electronic device is in a secondconfiguration, wherein the portable electronic device has a lid and thefirst display is located on an inside surface of the lid, and whereinthe second display is physically separate from the first display and thesecond display is located on an outside surface of the lid.
 9. Thearticle of manufacture of claim 8 wherein the instructions formonitoring for the event representative of the transition to the lowpower mode includes instructions for monitoring for a time interval whenthe transition to the low power mode is scheduled to occur.
 10. Thearticle of manufacture of claim 8 wherein the machine-readable storagemedium further includes instructions stored thereon to: download theportion of the second email to a storage location using a deliverymechanism of an email application installed in the portable electronicdevice; and synchronize at least some email content in the storagelocation to the memory, including synchronization of the downloadedportion of the second email into the memory.
 11. An apparatus thatoperates in a standby mode, a low power mode, and a higher power mode,wherein the standby mode uses less power than the low power mode and thelow power mode uses less power than the higher power mode, the apparatuscomprising: a network access device; an email component operable tocommunicate with the network access device to obtain at least a portionof an email during the higher power mode and the low power mode, to beinactive during the standby mode, to monitor for an event representativeof a transition from the standby mode to the low power mode, and totransition to the low power mode in response to the event; a memorycommunicatively coupled to the email component to store the obtainedportion of the email; a high-power processing unit configured to controlthe display of the portion of the email during the higher power mode; afirst display associated with the high power processing module, whereinthe high-power processing unit is configured to control the firstdisplay to display the portion of the email during the higher powermode; a low-power processing unit coupled to the memory and configuredto control presentation of the portion of the email stored thereinduring the low power mode or the standby mode; a second displayassociated with the low-power processing unit, wherein the seconddisplay is physically separate from the first display and wherein thelow-power processing unit is configured to control the second display todisplay the portion of the email during the low power mode; and ahousing having a lid for at least partially carrying the network accessdevice, the memory, the high power processing unit, the low powerprocessing unit, the first display, and the second display, wherein thehousing is sized to be held within a user's hand, wherein the firstdisplay is located on an inside surface of the lid, and wherein thesecond display is located on an outside surface of the lid, wherein theapparatus is configured to deactivate at least a first component of theapparatus that is to be unused for obtaining the at least a portion ofthe email during the low power mode, activate at least a secondcomponent of the apparatus that is to be used in conjunction with theemail component for obtaining the at least a portion of the email duringthe low power mode, and deactivate the second component after the atleast a portion of the email is obtained.
 12. The apparatus of claim 11,further comprising a user interface controllable by the low-powerprocessing unit to present the portion of the email.
 13. The apparatusof claim 12 wherein the memory, low-power processing unit, and the userinterface comprise part of a low power display module that can operateindependently of other components of the apparatus.
 14. The apparatus ofclaim 11, wherein the high-power processing unit can be transitionedinto the low power mode to control the email component and the networkaccess device to obtain the portion of the email.
 15. The apparatus ofclaim 11, further comprising a storage location to store the obtainedportion of the email, wherein the email component can performsynchronization between the storage location and the memory to match atleast some of their email content.
 16. The apparatus of claim 11,further comprising an application and an operating system associatedwith the low-power processing unit to cooperate with the low-powerprocessing unit to present the portion of the email.
 17. The apparatusof claim 11, further comprising an email application having a mailretrieval mechanism usable by the email component to obtain the portionof the email during the low power mode.